Layered double hydroxides (LDHs) have been designed and applied in environmental remediation based on their tunable physical structure and excellent chemical performance. To investigate the adsorption behavior of aqueous phosphate by the LDH‐based composite, zirconium‐modified Mg‐Al‐LDH (Zr‐LDH) was synthesized by the coprecipitation method, and subsequently calcined to obtain a layered double oxide (Zr‐LDO). Scanning electron microscopy, X‐ray diffraction, and Fourier transform infrared spectroscopy were used to describe the micromorphology, crystal structure, and functional groups of Zr‐LDH and Zr‐LDO, respectively. The as‐synthesized materials were subsequently selected as adsorbents to adsorb aqueous phosphate using batch equilibrium methods. The results showed that Zr‐LDH and Zr‐LDO can rapidly and efficiently reduce the phosphate concentration. The optimum dosage of LDH, Zr‐LDH, and Zr‐LDO was selected as 0.05 g. The adsorption efficiencies of Zr‐LDH and Zr‐LDO for phosphate were above 95% during the first 10 min. The experimental data agreed well with the pseudo‐second‐order equation, and the Langmuir and Freundlich equations. The maximum adsorption capacities of Zr‐LDH and Zr‐LDO were 99.35 and 80.33 mg/g, respectively. Moreover, the reaction process was spontaneous and endothermic. Zr‐LDH and Zr‐LDO have good reusability and selectivity, and are promising materials for aqueous phosphate removal. This work confirms that Zr‐LDH and Zr‐LDO can be selected as favorable sorbents to remove phosphate from wastewater.
An environment-friendly and economical magnetic composite, namely Fe3O4/GP, was produced from grapefruit peel (GP) and ferric chloride via the solvothermal method in one easy step, and was used to remove Congo red (CR), humic acid (HA), and phosphate (P) from aqueous
solutions. The Fourier transform infrared (FTIR) spectroscopy, X-ray diffraction (XRD), scanning electron microscope (SEM) procedures and specific surface area and zeta potential determination were applied to describe the structure of Fe3O4/GP composite. The results shown
the Fe3O4 particles, which fabricated during the solvothermal reaction, were distributed evenly on the surface of GP. Then Fe3O4/GP composite also presented a high level of magnetism, and thus could be separated quickly from suspension by an external
magnet. The adsorption efficiencies of Fe3O4/GP for CR, HA, and P were 92.88%, 47.45%, and 99.02%, which were found uninfluenced by the initial solution pH and attained the equilibrium state within 10 min. The kinetic and isothermal tests were performed and the data were
consistent with the pseudo-second-order kinetic equation and the Freundlich model.
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